Your search keyword '"Sadakuni, N."' showing total 17 results

1. 1-2.4 μm Near-IR Spectrum of the Giant Planet β Pictoris b Obtained with the Gemini Planet Imager

Author

Chilcote, J, Pueyo, L, Rosa, RJD, Vargas, J, Macintosh, B, Bailey, VP, Barman, T, Bauman, B, Bruzzone, S, Bulger, J, Burrows, AS, Cardwell, A, Chen, CH, Cotten, T, Dillon, D, Doyon, R, Draper, ZH, Duchêne, G, Dunn, J, Erikson, D, Fitzgerald, MP, Follette, KB, Gavel, D, Goodsell, SJ, Graham, JR, Greenbaum, AZ, Hartung, M, Hibon, P, Hung, LW, Ingraham, P, Kalas, P, Konopacky, Q, Larkin, JE, Maire, J, Marchis, F, Marley, MS, Marois, C, Metchev, S, Millar-Blanchaer, MA, Morzinski, KM, Nielsen, EL, Norton, A, Oppenheimer, R, Palmer, D, Patience, J, Perrin, M, Poyneer, L, Rajan, A, Rameau, J, Rantakyrö, FT, Sadakuni, N, Saddlemyer, L, Savransky, D, Schneider, AC, Serio, A, Sivaramakrishnan, A, Song, I, Soummer, R, Thomas, S, Wallace, JK, Wang, JJ, Ward-Duong, K, Wiktorowicz, S, and Wolff, S

Subjects

instrumentation: adaptive optics, planetary systems, stars: individual, techniques:spectroscopic, astro-ph.EP, Astronomy & Astrophysics, Astronomical and Space Sciences

Abstract

Using the Gemini Planet Imager located at Gemini South, we measured the near-infrared (1.0-2.4 μm) spectrum of the planetary companion to the nearby, young star β Pictoris. We compare the spectrum obtained with currently published model grids and with known substellar objects and present the best matching models as well as the best matching observed objects. Comparing the empirical measurement of the bolometric luminosity to evolutionary models, we find a mass of 12.9 ±0.2 , an effective temperature of 1724 ±15 K, a radius of 1.46 ±0.01 , and a surface gravity of [dex] (cgs). The stated uncertainties are statistical errors only, and do not incorporate any uncertainty on the evolutionary models. Using atmospheric models, we find an effective temperature of 1700-1800 K and a surface gravity of -4.0 [dex] depending upon the model. These values agree well with other publications and with "hot-start" predictions from planetary evolution models. Further, we find that the spectrum of β Pic b best matches a low surface gravity L2 ±1 brown dwarf. Finally, comparing the spectrum to field brown dwarfs, we find the the spectrum best matches 2MASS J04062677-381210 and 2MASS J03552337+1133437.

Published

2017

2. An M-dwarf star in the transition disk of Herbig HD 142527; Physical parameters and orbital elements

Author

Lacour, S., Biller, B., Cheetham, A., Greenbaum, A., Pearce, T., Marino, S., Tuthill, P., Pueyo, L., Mamajek, E. E., Girard, J. H., Sivaramakrishnan, A., Bonnefoy, M., Baraffe, I., Chauvin, G., Olofsson, J., Juhasz, A., Benisty, M., Pott, J. -U., Sicilia-Aguilar, A., Henning, T., Cardwell, A., Goodsell, S., Graham, J. R., Hibon, P., Ingraham, P., Konopacky, Q., Macintosh, B., Oppenheimer, R., Perrin, M., Rantakyrö, F., Sadakuni, N., and Thomas, S.

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

HD 142527A is one of the most studied Herbig Ae/Be stars with a transitional disk, as it has the largest imaged gap in any protoplanetary disk: the gas is cleared from 30 to 90 AU. The HD142527 system is also unique in that it has a stellar companion with a small mass compared to the mass of the primary star. This factor of ~20 in mass ratio between the two objects makes this binary system different from any other YSO. The HD142527 system could therefore provide a valuable test bed. This low-mass stellar object may be responsible for both the gap and dust trapping observed by ALMA at longer distances. We observed this system with the NACO and GPI instruments using the aperture masking technique. Aperture masking is ideal for providing high dynamic range even at very small angular separations. We present the spectral energy distribution for HD142527A and B. Brightness of the companion is now known from the R band up to the M' band. We also followed the orbital motion of HD 142527B over a period of more than two years. The SED of the companion is compatible with a T=3000+/-100K object in addition to a 1700K blackbody environment (likely a circus-secondary disk). From evolution models, we find that it is compatible with an object of mass 0.13+/-0.03Msun, radius 0.90+/-0.15Rsun, and age $1.0^{+1.0}_{-0.75}$Myr. This age is significantly younger than the age previously estimated for HD142527A. Computations to constrain the orbital parameters found a semi major axis of $140^{+120}_{-70}$mas, an eccentricity of 0.5+/-0.2, an inclination of 125+/-15 degrees, and a position angle of the right ascending node of -5+/-40 degrees. Inclination and position angle of the ascending node are in agreement with an orbit coplanar with the inner disk, not coplanar with the outer disk. Despite its high eccentricity, it is unlikely that HD142527B is responsible for truncating the inner edge of the outer disk., Comment: published in A&A; 8 pages

Published

2015

3. Discovery and spectroscopy of the young Jovian planet 51 Eri b with the Gemini Planet Imager

Author

Macintosh, B., Graham, J. R., Barman, T., De Rosa, R. J., Konopacky, Q., Marley, M. S., Marois, C., Nielsen, E. L., Pueyo, L., Rajan, A., Rameau, J., Saumon, D., Wang, J. J., Patience, J., Ammons, M., Arriaga, P., Artigau, E., Beckwith, S., Brewster, J., Bruzzone, S., Bulger, J., Burningham, B., Burrows, A. S., Chen, C., Chiang, E., Chilcote, J. K., Dawson, R. I., Dong, R., Doyon, R., Draper, Z. H., Duchêne, G., Esposito, T. M., Fabrycky, D., Fitzgerald, M. P., Follette, K. B., Fortney, J. J., Gerard, B., Goodsell, S., Greenbaum, A. Z., Hibon, P., Hinkley, S., Cotten, T. H., Hung, L. -W., Ingraham, P., Johnson-Groh, M., Kalas, P., Lafreniere, D., Larkin, J. E., Lee, J., Line, M., Long, D., Maire, J., Marchis, F., Matthews, B. C., Max, C. E., Metchev, S., Millar-Blanchaer, M. A., Mittal, T., Morley, C. V., Morzinski, K. M., Murray-Clay, R., Oppenheimer, R., Palmer, D. W., Patel, R., Perrin, M. D., Poyneer, L. A., Rafikov, R. R., Rantakyrö, F. T., Rice, E. L., Rojo, P., Rudy, A. R., Ruffio, J. -B., Ruiz, M. T., Sadakuni, N., Saddlemyer, L., Salama, M., Savransky, D., Schneider, A. C., Sivaramakrishnan, A., Song, I., Soummer, R., Thomas, S., Vasisht, G., Wallace, J. K., Ward-Duong, K., Wiktorowicz, S. J., Wolff, S. G., and Zuckerman, B.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

Directly detecting thermal emission from young extrasolar planets allows measurement of their atmospheric composition and luminosity, which is influenced by their formation mechanism. Using the Gemini Planet Imager, we discovered a planet orbiting the \$sim$20 Myr-old star 51 Eridani at a projected separation of 13 astronomical units. Near-infrared observations show a spectrum with strong methane and water vapor absorption. Modeling of the spectra and photometry yields a luminosity of L/LS=1.6-4.0 x 10-6 and an effective temperature of 600-750 K. For this age and luminosity, "hot-start" formation models indicate a mass twice that of Jupiter. This planet also has a sufficiently low luminosity to be consistent with the "cold- start" core accretion process that may have formed Jupiter., Comment: 29 pages, 3 figures, 2 tables, and Supplementary Materials. published in Science Express on Aug 13 2015. List of authors and the magnitudes of the star were correted

Published

2015

4. Discovery and spectroscopy of the young jovian planet 51 Eri b with the Gemini Planet Imager.

Author

Macintosh, B, Graham, JR, Barman, T, De Rosa, RJ, Konopacky, Q, Marley, MS, Marois, C, Nielsen, EL, Pueyo, L, Rajan, A, Rameau, J, Saumon, D, Wang, JJ, Patience, J, Ammons, M, Arriaga, P, Artigau, E, Beckwith, S, Brewster, J, Bruzzone, S, Bulger, J, Burningham, B, Burrows, AS, Chen, C, Chiang, E, Chilcote, JK, Dawson, RI, Dong, R, Doyon, R, Draper, ZH, Duchêne, G, Esposito, TM, Fabrycky, D, Fitzgerald, MP, Follette, KB, Fortney, JJ, Gerard, B, Goodsell, S, Greenbaum, AZ, Hibon, P, Hinkley, S, Cotten, TH, Hung, L-W, Ingraham, P, Johnson-Groh, M, Kalas, P, Lafreniere, D, Larkin, JE, Lee, J, Line, M, Long, D, Maire, J, Marchis, F, Matthews, BC, Max, CE, Metchev, S, Millar-Blanchaer, MA, Mittal, T, Morley, CV, Morzinski, KM, Murray-Clay, R, Oppenheimer, R, Palmer, DW, Patel, R, Perrin, MD, Poyneer, LA, Rafikov, RR, Rantakyrö, FT, Rice, EL, Rojo, P, Rudy, AR, Ruffio, J-B, Ruiz, MT, Sadakuni, N, Saddlemyer, L, Salama, M, Savransky, D, Schneider, AC, Sivaramakrishnan, A, Song, I, Soummer, R, Thomas, S, Vasisht, G, Wallace, JK, Ward-Duong, K, Wiktorowicz, SJ, Wolff, SG, and Zuckerman, B

Subjects

astro-ph.EP, General Science & Technology

Abstract

Directly detecting thermal emission from young extrasolar planets allows measurement of their atmospheric compositions and luminosities, which are influenced by their formation mechanisms. Using the Gemini Planet Imager, we discovered a planet orbiting the ~20-million-year-old star 51 Eridani at a projected separation of 13 astronomical units. Near-infrared observations show a spectrum with strong methane and water-vapor absorption. Modeling of the spectra and photometry yields a luminosity (normalized by the luminosity of the Sun) of 1.6 to 4.0 × 10(-6) and an effective temperature of 600 to 750 kelvin. For this age and luminosity, "hot-start" formation models indicate a mass twice that of Jupiter. This planet also has a sufficiently low luminosity to be consistent with the "cold-start" core-accretion process that may have formed Jupiter.

Published

2015

5. Gemini planet imager observations of the au microscopii debris disk: Asymmetries within one arcsecond

Author

Wang, JJ, Graham, JR, Pueyo, L, Nielsen, EL, Millar-Blanchaer, M, Rosa, RJD, Kalas, P, Ammons, SM, Bulger, J, Cardwell, A, Chen, C, Chiang, E, Chilcote, JK, Doyon, R, Draper, ZH, Duchêne, G, Esposito, TM, Fitzgerald, MP, Goodsell, SJ, Greenbaum, AZ, Hartung, M, Hibon, P, Hinkley, S, Hung, LW, Ingraham, P, Larkin, JE, Macintosh, B, Maire, J, Marchis, F, Marois, C, Matthews, BC, Morzinski, KM, Oppenheimer, R, Patience, J, Perrin, MD, Rajan, A, Rantakyrö, FT, Sadakuni, N, Serio, A, Sivaramakrishnan, A, Soummer, R, Thomas, S, Ward-Duong, K, Wiktorowicz, SJ, and Wolff, SG

Subjects

circumstellar matter, instrumentation: adaptive optics, methods: data analysis, planet-disk interactions, stars: individual, techniques: high angular resolution, astro-ph.EP, Astronomy & Astrophysics, Astronomical and Space Sciences

Abstract

We present Gemini Planet Imager (GPI) observations of AU Microscopii, a young M dwarf with an edge-on, dusty debris disk. Integral field spectroscopy and broadband imaging polarimetry were obtained during the commissioning of GPI. In our broadband imaging polarimetry observations, we detect the disk only in total intensity and find asymmetries in the morphology of the disk between the southeast (SE) and northwest (NW) sides. The SE side of the disk exhibits a bump at 1″ (10 AU projected separation) that is three times more vertically extended and three times fainter in peak surface brightness than the NW side at similar separations. This part of the disk is also vertically offset by 69 ± 30 mas to the northeast at 1″ when compared to the established disk midplane and is consistent with prior Atacama Large Millimeter/submillimeter Array and Hubble Space Telescope/Space Telescope Imaging Spectrograph observations. We see hints that the SE bump might be a result of detecting a horizontal sliver feature above the main disk that could be the disk backside. Alternatively, when including the morphology of the NW side, where the disk midplane is offset in the opposite direction ∼50 mas between 0.″4 and 1.″2, the asymmetries suggest a warp-like feature. Using our integral field spectroscopy data to search for planets, we are 50% complete for ∼4 MJup planets at 4 AU. We detect a source, resolved only along the disk plane, that could either be a candidate planetary mass companion or a compact clump in the disk.

Published

2015

6. β PICTORIS' INNER DISK in POLARIZED LIGHT and NEW ORBITAL PARAMETERS for β PICTORIS b

Author

Millar-Blanchaer, MA, Graham, JR, Pueyo, L, Kalas, P, Dawson, RI, Wang, J, Perrin, MD, Moon, DS, Macintosh, B, Ammons, SM, Barman, T, Cardwell, A, Chen, CH, Chiang, E, Chilcote, J, Cotten, T, Rosa, RJD, Draper, ZH, Dunn, J, Duchêne, G, Esposito, TM, Fitzgerald, MP, Follette, KB, Goodsell, SJ, Greenbaum, AZ, Hartung, M, Hibon, P, Hinkley, S, Ingraham, P, Jensen-Clem, R, Konopacky, Q, Larkin, JE, Long, D, Maire, J, Marchis, F, Marley, MS, Marois, C, Morzinski, KM, Nielsen, EL, Palmer, DW, Oppenheimer, R, Poyneer, L, Rajan, A, Rantakyrö, FT, Ruffio, JB, Sadakuni, N, Saddlemyer, L, Schneider, AC, Sivaramakrishnan, A, Soummer, R, Thomas, S, Vasisht, G, Vega, D, Wallace, JK, Ward-Duong, K, Wiktorowicz, SJ, and Wolff, SG

Subjects

astrometry, planet-disk interactions, planets and satellites: individual, techniques: polarimetric, astro-ph.EP, Astronomy & Astrophysics, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural)

Abstract

We present H-band observations of β Pic with the Gemini Planet Imager's (GPI's) polarimetry mode that reveal the debris disk between ∼0.″3 (6 AU) and ∼1.″7 (33 AU), while simultaneously detecting β Pic b. The polarized disk image was fit with a dust density model combined with a Henyey-Greenstein scattering phase function. The best-fit model indicates a disk inclined to the line of sight () with a position angle (PA) (slightly offset from the main outer disk, ), that extends from an inner disk radius of to well outside GPI's field of view. In addition, we present an updated orbit for β Pic b based on new astrometric measurements taken in GPI's spectroscopic mode spanning 14 months. The planet has a semimajor axis of , with an eccentricity The PA of the ascending node is offset from both the outer main disk and the inner disk seen in the GPI image. The orbital fit constrains the stellar mass of β Pic to Dynamical sculpting by β Pic b cannot easily account for the following three aspects of the inferred disk properties: (1) the modeled inner radius of the disk is farther out than expected if caused by β Pic b; (2) the mutual inclination of the inner disk and β Pic b is when it is expected to be closer to zero; and (3) the aspect ratio of the disk () is larger than expected from interactions with β Pic b or self-stirring by the disk's parent bodies.

Published

2015

7. Polarimetry with the gemini planet imager: Methods, performance at first light, and the circumstellar ring around HR 4796A

Author

Perrin, MD, Duchene, G, Millar-Blanchaer, M, Fitzgerald, MP, Graham, JR, Wiktorowicz, SJ, Kalas, PG, Macintosh, B, Bauman, B, Cardwell, A, Chilcote, J, De Rosa, RJ, Dillon, D, Doyon, R, Dunn, J, Erikson, D, Gavel, D, Goodsell, S, Hartung, M, Hibon, P, Ingraham, P, Kerley, D, Konapacky, Q, Larkin, JE, Maire, J, Marchis, F, Marois, C, Mittal, T, Morzinski, KM, Oppenheimer, BR, Palmer, DW, Patience, J, Poyneer, L, Pueyo, L, Rantakyrö, FT, Sadakuni, N, Saddlemyer, L, Savransky, D, Soummer, R, Sivaramakrishnan, A, Song, I, Thomas, S, Wallace, JK, Wang, JJ, and Wolff, SG

Subjects

circumstellar matter, instrumentation: adaptive optics, instrumentation: high angular resolution, instrumentation: polarimeters, polarization, stars: individual, astro-ph.EP, astro-ph.IM, Astronomy & Astrophysics, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural)

Abstract

We present the first results from the polarimetry mode of the Gemini Planet Imager (GPI), which uses anew integral field polarimetry architecture to provide high contrast linear polarimetry with minimal systematic biases between the orthogonal polarizations. We describe the design, data reduction methods, and performance of polarimetry with GPI. Point-spread function (PSF) subtraction via differential polarimetry suppresses unpolarized starlight by a factor of over 100, and provides sensitivity to circumstellar dust reaching the photon noise limit for these observations. in the case of the circumstellar disk around HR 4796A,GPI's advanced adaptive optics system reveals the disk clearly even prior to PSF subtraction. In polarized light, the disk is seen all the way in to its semi-minor axis for the first time. The disk exhibits surprisingly strong asymmetry in polarized intensity, with the west side ≳9 times brighter than the east side despite the fact that the east side is slightly brighter in total intensity. Based on a synthesis of the total and polarized intensities, we now believe that the west side is closer to us, contrary to most prior interpretations. Forward scattering by relatively large silicate dust particles leads to the strong polarized intensity on thewest side, and the ring must be slightly optically thick in order to explain the lower brightness in total intensity there. These findings suggest that the ring is geometrically narrow and dynamically cold, perhaps shepherded by larger bodies in the same manner as Saturn's Fring.

Published

2015

8. The first H-band spectrum of the giant planet β Pictoris b

Author

Chilcote, J, Barman, T, Fitzgerald, MP, Graham, JR, Larkin, JE, Macintosh, B, Bauman, B, Burrows, AS, Cardwell, A, De Rosa, RJ, Dillon, D, Doyon, R, Dunn, J, Erikson, D, Gavel, D, Goodsell, SJ, Hartung, M, Hibon, P, Ingraham, P, Kalas, P, Konopacky, Q, Maire, J, Marchis, F, Marley, MS, Marois, C, Millar-Blanchaer, M, Morzinski, K, Norton, A, Oppenheimer, R, Palmer, D, Patience, J, Perrin, M, Poyneer, L, Pueyo, L, Rantakyrö, FT, Sadakuni, N, Saddlemyer, L, Savransky, D, Serio, A, Sivaramakrishnan, A, Song, I, Soummer, R, Thomas, S, Wallace, JK, Wiktorowicz, S, and Wolff, S

Subjects

infrared: general, instrumentation: adaptive optics, planetary systems, stars: individual, techniques: spectroscopic, Astronomy & Astrophysics, Astronomical and Space Sciences

Abstract

Using the recently installed Gemini Planet Imager (GPI), we have obtained the first H-band spectrum of the planetary companion to the nearby young star β Pictoris. GPI is designed to image and provide low-resolution spectra of Jupiter-sized, self-luminous planetary companions around young nearby stars. These observations were taken covering the H band (1.65 μm). The spectrum has a resolving power of ∼45 and demonstrates the distinctive triangular shape of a cool substellar object with low surface gravity. Using atmospheric models, we find an effective temperature of 1600-1700K and a surface gravity of log(g) = 3.5-4.5 (cgs units). These values agree well with "hot-start" predictions from planetary evolution models for a gas giant with mass between 10 and 12 MJup and age between 10 and 20 Myr.

Published

2015

9. Final A&T Stages of the Gemini Planet Finder

Author

Hartung, M., Macintosh, B., Poyneer, L., Savransky, D., Gavel, D., Palmer, D., Thomas, S., Dillon, D., Chilcote, J., Ingraham, P., Sadakuni, N., Wallace, K., Perin, M. D., Marois, C., Maire, J., Rantakyro, F., Hibon, P., Saddlemyer, L., and Goodsell, S.

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

The Gemini Planet Imager (GPI) is currently in its final Acceptance & Testing stages. GPI is an XAO system based on a tweeter & woofer architecture (43 & 9 actuators respectively across the pupil), with the tweeter being a Boston Michromachines $64^2$ MEMS device. The XAO AO system is tightly integrated with a Lyot apodizing coronagraph. Acceptance testing started in February 2013 at the University of California, Santa Cruz. A conclusive acceptance review was held in July 2013 and the instrument was found ready for shipment to the Gemini South telescope on Cerro Pachon, Chile. Commissioning at the telescope will take place by the end of 2013, matching the summer window of the southern hemisphere. According to current estimates the 3 year planet finding campaign (890 allocated hours) might discover, image, and spectroscopically analyze 20 to 40 new exo-planets. Final acceptance testing of the integrated instrument can always bring up surprises when using cold chamber and flexure rig installations. The latest developments are reported. Also, we will give an overview of GPI's lab performance, the interplay between subsystems such as the calibration unit (CAL) with the AO bench. We report on-going optimizations on the AO controller loop to filter vibrations and last but not least achieved contrast performance applying speckle nulling. Furthermore, we will give an outlook of possible but challenging future upgrades as the implementation of a predictive controller or exchanging the conventional 48x48 SH WFS with a pyramid. With the ELT era arising, GPI will proof as a versatile and path-finding testbed for AO technologies on the next generation of ground-based telescopes., Comment: 10 pages, 6 figures, submitted to Proceedings of AO4ELT3 conference, Florence, Italy, May 2013

Published

2013

10. Gemini planet imager spectroscopy of the HR 8799 planets c and d

Author

Ingraham, P, Marley, MS, Saumon, D, Marois, C, Macintosh, B, Barman, T, Bauman, B, Burrows, A, Chilcote, JK, De Rosa, RJ, Dillon, D, Doyon, R, Dunn, J, Erikson, D, Fitzgerald, MP, Gavel, D, Goodsell, SJ, Graham, JR, Hartung, M, Hibon, P, Kalas, PG, Konopacky, Q, Larkin, JA, Maire, J, Marchis, F, McBride, J, Millar-Blanchaer, M, Morzinski, KM, Norton, A, Oppenheimer, R, Palmer, DW, Patience, J, Perrin, MD, Poyneer, LA, Pueyo, L, Rantakyrö, F, Sadakuni, N, Saddlemyer, L, Savransky, D, Soummer, R, Sivaramakrishnan, A, Song, I, Thomas, S, Kent Wallace, J, Wiktorowicz, SJ, and Wolff, SG

Subjects

infrared: planetary systems, instrumentation: adaptive optics, instrumentation: high angular resolution, planets and satellites: atmospheres, planets and satellites: gaseous planets, techniques: imaging spectroscopy, Astronomy & Astrophysics, Astronomical and Space Sciences

Abstract

During the first-light run of the Gemini Planet Imager we obtained K-band spectra of exoplanets HR 8799 c and d. Analysis of the spectra indicates that planet d may be warmer than planet c. Comparisons to recent patchy cloud models and previously obtained observations over multiple wavelengths confirm that thick clouds combined with horizontal variation in the cloud cover generally reproduce the planets' spectral energy distributions. When combined with the 3 to 4 μm photometric data points, the observations provide strong constraints on the atmospheric methane content for both planets. The data also provide further evidence that future modeling efforts must include cloud opacity, possibly including cloud holes, disequilibrium chemistry, and super-solar metallicity.

Published

2014

11. PLANETARY SCIENCE: Discovery and spectroscopy of the young jovian planet 51 Eri b with the Gemini Planet Imager

Author

Macintosh, B., Graham, J. R., Barman, T., De Rosa, R. J., Konopacky, Q., Marley, M. S., Marois, C., Nielsen, E. L., Pueyo, L., Rajan, A., Rameau, J., Saumon, D., Wang, J. J., Patience, J., Ammons, M., Arriaga, P., Artigau, E., Beckwith, S., Brewster, J., Bruzzone, S., Bulger, J., Burningham, B., Burrows, A. S., Chen, C., Chiang, E., Chilcote, J. K., Dawson, R. I., Dong, R., Doyon, R., Draper, Z. H., Duchêne, G., Esposito, T. M., Fabrycky, D., Fitzgerald, M. P., Follette, K. B., Fortney, J. J., Gerard, B., Goodsell, S., Greenbaum, A. Z., Hibon, P., Hinkley, S., Cotten, T. H., Hung, L.-W., Ingraham, P., Johnson-Groh, M., Kalas, P., Lafreniere, D., Larkin, J. E., Lee, J., Line, M., Long, D., Maire, J., Marchis, F., Matthews, B. C., Max, C. E., Metchev, S., Millar-Blanchaer, M. A., Mittal, T., Morley, C. V., Morzinski, K. M., Murray-Clay, R., Oppenheimer, R., Palmer, D. W., Patel, R., Perrin, M. D., Poyneer, L. A., Rafikov, R. R., Rantakyrö, F. T., Rice, E. L., Rojo, P., Rudy, A. R., Ruffio, J.-B., Ruiz, M. T., Sadakuni, N., Saddlemyer, L., Salama, M., Savransky, D., Schneider, A. C., Sivaramakrishnan, A., Song, I., Soummer, R., Thomas, S., Vasisht, G., Wallace, J. K., Ward-Duong, K., Wiktorowicz, S. J., Wolff, S. G., and Zuckerman, B.

Published

2015

12. An M-dwarf star in the transition disk of Herbig HD 142527

Author

Lacour, S., Biller, B., Cheetham, A., Greenbaum, A., Pearce, T., Marino, S., Tuthill, P., Pueyo, L., Mamajek, E. E., Girard, J. H., Sivaramakrishnan, A., Bonnefoy, M., Baraffe, I., Chauvin, G., Olofsson, J., Juhasz, A., Benisty, M., Pott, J.-U., Sicilia-Aguilar, A., Henning, T., Cardwell, A., Goodsell, S., Graham, J. R., Hibon, P., Ingraham, P., Konopacky, Q., Macintosh, B., Oppenheimer, R., Perrin, M., Rantakyrö, F., Sadakuni, N., Thomas, S., Institut Européen des membranes (IEM), Université de Montpellier (UM)-Université Montpellier 2 - Sciences et Techniques (UM2)-Ecole Nationale Supérieure de Chimie de Montpellier (ENSCM)-Centre National de la Recherche Scientifique (CNRS), Laboratoire d'études spatiales et d'instrumentation en astrophysique (LESIA), Centre National de la Recherche Scientifique (CNRS)-Université Paris Diderot - Paris 7 (UPD7)-Observatoire de Paris, PSL Research University (PSL)-PSL Research University (PSL)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC), Max-Planck-Institut für Astronomie (MPIA), Max-Planck-Gesellschaft, Observatoire Astronomique de l'Université de Genève (ObsGE), Université de Genève (UNIGE), Sydney Institute for Astronomy (SIfA), The University of Sydney, Space Telescope Science Institute (STSci), Institut de Planétologie et d'Astrophysique de Grenoble (IPAG), Centre National d'Études Spatiales [Toulouse] (CNES)-Université Grenoble Alpes (UGA)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire des Sciences de l'Univers de Grenoble (OSUG), Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Université Joseph Fourier - Grenoble 1 (UJF)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Université Joseph Fourier - Grenoble 1 (UJF)-Centre National de la Recherche Scientifique (CNRS), Centre de Recherche Astrophysique de Lyon (CRAL), École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Universidad Autonoma de Madrid (UAM), European Southern Observatory (ESO), IRSN - LABORATOIRE DE MESURE DE LA RADIOACTIVITE DANS L'ENVIRONNEMENT, IRSN - LABORATOIRE DE MESURE DE LA RADIOACTIVITE DANS L'ENVIRONNEMENT,Bois des Rames, 91400, Orsay, France, Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), Université de Genève = University of Geneva (UNIGE), Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Observatoire des Sciences de l'Univers de Grenoble (OSUG ), Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut national des sciences de l'Univers (INSU - CNRS)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019])-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019]), École normale supérieure de Lyon (ENS de Lyon)-Université Claude Bernard Lyon 1 (UCBL), Universidad Autónoma de Madrid (UAM), Laboratoire de Mesure de la Radioactivité dans l'Environnement (IRSN/DEI/STEME/LMRE), Institut de Radioprotection et de Sûreté Nucléaire (IRSN), and Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)

Subjects

[PHYS]Physics [physics], [PHYS.ASTR]Physics [physics]/Astrophysics [astro-ph], ComputingMilieux_MISCELLANEOUS

Abstract

International audience; Aims. HD 42527A is one of the most studied Herbig Ae/Be stars with a transitional disk, as it has the largest imaged gap in any protoplanetary disk: the gas is cleared from 30 to 90 AU. The HD 142527 system is also unique in that it has a stellar companion with a small mass compared to the mass of the primary star. This factor of ≈20 in mass ratio between the two objects makes this binary system different from any other YSO. The HD 142527 system could therefore provide a valuable test bed for understanding the impact of a lower mass companion on disk structure. This low-mass stellar object may be responsible for both the gap and dust trapping observed by ALMA at longer distances.Methods. We observed this system with the NACO and GPI instruments using the aperture masking technique. Aperture masking is ideal for providing high dynamic range even at very small angular separations. We present the spectral energy distribution (SED) for HD 142527A and B. Brightness of the companion is now known from the R band up to the M′ band. We also followed the orbital motion of HD 142527B over a period of more than two years.Results. The SED of the companion is compatible with a T = 3000 ± 100 K object in addition to a 1700 K blackbody environment (likely a circum-secondary disk). From evolution models, we find that it is compatible with an object of mass 0.13 ± 0.03 M⊙, radius 0.90 ± 0.15 R⊙, and age 1.0+1.0-0.75 Myr. This age is significantly younger than the age previously estimated for HD 142527A. Computations to constrain the orbital parameters found a semimajor axis of 140+120-70 mas, an eccentricity of 0.5 ± 0.2, an inclination of 125 ± 15 degrees, and a position angle of the right ascending node of −5 ± 40 degrees. Inclination and position angle of the ascending node are in agreement with an orbit coplanar with the inner disk, not coplanar with the outer disk. Despite its high eccentricity, it is unlikely that HD 142527B is responsible for truncating the inner edge of the outer disk.

Published

2016

13. Final A&T stages of the Gemini Planet Finder

Author

Hartung, M., Macintosh, B., Poyneer, L., Savransky, D., Gavel, D., Palmer, D., Thomas, S., Dillon, D., Chilcote, J., Ingraham, P., Sadakuni, N., Wallace, K., Perin, M. D., Marois, C., Maire, J., Rantakyro, F., Hibon, P., Saddlemyer, L., and Goodsell, S.

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

The Gemini Planet Imager (GPI) is currently in its final Acceptance & Testing stages. GPI is an XAO system based on a tweeter & woofer architecture (43 & 9 actuators respectively across the pupil), with the tweeter being a Boston Michromachines $64^2$ MEMS device. The XAO AO system is tightly integrated with a Lyot apodizing coronagraph. Acceptance testing started in February 2013 at the University of California, Santa Cruz. A conclusive acceptance review was held in July 2013 and the instrument was found ready for shipment to the Gemini South telescope on Cerro Pachon, Chile. Commissioning at the telescope will take place by the end of 2013, matching the summer window of the southern hemisphere. According to current estimates the 3 year planet finding campaign (890 allocated hours) might discover, image, and spectroscopically analyze 20 to 40 new exo-planets. Final acceptance testing of the integrated instrument can always bring up surprises when using cold chamber and flexure rig installations. The latest developments are reported. Also, we will give an overview of GPI's lab performance, the interplay between subsystems such as the calibration unit (CAL) with the AO bench. We report on-going optimizations on the AO controller loop to filter vibrations and last but not least achieved contrast performance applying speckle nulling. Furthermore, we will give an outlook of possible but challenging future upgrades as the implementation of a predictive controller or exchanging the conventional 48x48 SH WFS with a pyramid. With the ELT era arising, GPI will proof as a versatile and path-finding testbed for AO technologies on the next generation of ground-based telescopes., Comment: 10 pages, 6 figures, submitted to Proceedings of AO4ELT3 conference, Florence, Italy, May 2013

Published

2015

14. VizieR Online Data Catalog: 51 Eri b near-infrared spectrum (Macintosh+, 2015)

Author

Macintosh, B., Graham, J. R., Barman, T., Rosa, R. J., Konopacky, Q., Marley, M. S., Marois, C., Nielsen, E. L., Pueyo, L., Rajan, A., Rameau, J., Saumon, D., Jason Wang, Ammons, M., Arriaga, P., Artigau, E., Beckwith, S., Brewster, J., Bruzzone, S., Bulger, J., Burningham, B., Burrows, A. S., Chen, C., Chiang, E., Chilcote, J. K., Dawson, R. I., Dong, R., Doyon, R., Draper, Z. H., Duchene, G., Esposito, T. M., Fabrycky, D., Fitzgerald, M. P., Follette, K. B., Fortney, J. J., Gerard, B., Goodsell, S., Greenbaum, A. Z., Hibon, P., Hinkley, S., Hufford, T., Hung, L. -W, Ingraham, P., Johnson-Groh, M., Kalas, P., Lafreniere, D., Larkin, J. E., Lee, J., Line, M., Long, D., Maire, J., Marchis, F., Matthews, B. C., Max, C. E., Metchev, S., Millar-Blanchaer, M. A., Mittal, T., Morley, C. V., Morzinski, K. M., Murray-Clay, R., Oppenheimer, R., Palmer, D. W., Patel, R., Patience, J., Perrin, M. D., Poyneer, L. A., Rafikov, R. R., Rantakyro, F. T., Rice, E., Rojo, P., Rudy, A. R., Ruffio, J. -B, Ruiz, M. T., Sadakuni, N., Saddlemyer, L., Salama, M., Savransky, D., Schneider, A. C., Sivarama Krishnan, A., Song, I., Soummer, R., Thomas, S., Vasisht, G., Wallace, J. K., Ward-Duong, K., Wiktorowicz, S. J., Wolff, S. G., and Zuckerman, B.

15. Observations of Beta Pictoris b with the Gemini Planet Imager

Author

Chilcote, J., Graham, J., Barman, T., Fitzgerald, M., Larkin, J., Macintosh, B., Bauman, B., Burrows, A., Cardwell, A., Rosa, R., Dillon, D., Doyon, R., Dunn, J., Erikson, D., Gavel, D., Goodsell, S., Hartung, M., Hibon, P., Ingraham, P., Kalas, P., Konopacky, Q., Maire, J., Marchis, F., Marley, M., Mcbride, J., Millar-Blanchaer, M., Morzinski, K., Norton, A., Rebecca Oppenheimer, Palmer, D., Patience, J., Pueyo, L., Rantakyro, F., Sadakuni, N., Saddlemyer, L., Savransky, D., Serio, A., Soummer, R., Sivaramakrishnan, A., Song, I., Thomas, S., Wallace, K., Wiktorowicz, S., and Wolff, S.

16. Performance of the Gemini Planet Imager's adaptive optics system.

Author

Poyneer LA, Palmer DW, Macintosh B, Savransky D, Sadakuni N, Thomas S, Véran JP, Follette KB, Greenbaum AZ, Ammons SM, Bailey VP, Bauman B, Cardwell A, Dillon D, Gavel D, Hartung M, Hibon P, Perrin MD, Rantakyrö FT, Sivaramakrishnan A, and Wang JJ

Abstract

The Gemini Planet Imager's adaptive optics (AO) subsystem was designed specifically to facilitate high-contrast imaging. A definitive description of the system's algorithms and technologies as built is given. 564 AO telemetry measurements from the Gemini Planet Imager Exoplanet Survey campaign are analyzed. The modal gain optimizer tracks changes in atmospheric conditions. Science observations show that image quality can be improved with the use of both the spatially filtered wavefront sensor and linear-quadratic-Gaussian control of vibration. The error budget indicates that for all targets and atmospheric conditions AO bandwidth error is the largest term.

Published

2016

17. First light of the Gemini Planet imager.

Author

Macintosh B, Graham JR, Ingraham P, Konopacky Q, Marois C, Perrin M, Poyneer L, Bauman B, Barman T, Burrows AS, Cardwell A, Chilcote J, De Rosa RJ, Dillon D, Doyon R, Dunn J, Erikson D, Fitzgerald MP, Gavel D, Goodsell S, Hartung M, Hibon P, Kalas P, Larkin J, Maire J, Marchis F, Marley MS, McBride J, Millar-Blanchaer M, Morzinski K, Norton A, Oppenheimer BR, Palmer D, Patience J, Pueyo L, Rantakyro F, Sadakuni N, Saddlemyer L, Savransky D, Serio A, Soummer R, Sivaramakrishnan A, Song I, Thomas S, Wallace JK, Wiktorowicz S, and Wolff S

Abstract

The Gemini Planet Imager is a dedicated facility for directly imaging and spectroscopically characterizing extrasolar planets. It combines a very high-order adaptive optics system, a diffraction-suppressing coronagraph, and an integral field spectrograph with low spectral resolution but high spatial resolution. Every aspect of the Gemini Planet Imager has been tuned for maximum sensitivity to faint planets near bright stars. During first-light observations, we achieved an estimated H band Strehl ratio of 0.89 and a 5-σ contrast of 10(6) at 0.75 arcseconds and 10(5) at 0.35 arcseconds. Observations of Beta Pictoris clearly detect the planet, Beta Pictoris b, in a single 60-s exposure with minimal postprocessing. Beta Pictoris b is observed at a separation of 434 ± 6 milliarcseconds (mas) and position angle 211.8 ± 0.5°. Fitting the Keplerian orbit of Beta Pic b using the new position together with previous astrometry gives a factor of 3 improvement in most parameters over previous solutions. The planet orbits at a semimajor axis of [Formula: see text] near the 3:2 resonance with the previously known 6-AU asteroidal belt and is aligned with the inner warped disk. The observations give a 4% probability of a transit of the planet in late 2017.

Published

2014